Development of a Thermo-Hydro-Geochemical Model for Low-Temperature Geoexchange Applications

F. Eppner [1], P. Pasquier [1], P. Baudron [1],
[1] École Polytechnique de Montréal, Montréal, QC, Canada
Published in 2015

Standing column wells (SCW) are open-loop geoexchange systems used to provide space heating and cooling to buildings. As they use groundwater as heat carrier fluid and modify its thermo-chemical conditions along the year, they may favor calcite dissolution and precipitation, thus increasing maintenance costs. In order to predict the thermo-hydro-chemical (THC) processes occurring in a SCW and its surrounding geological environment, a 2D axisymmetric coupled multiphysics model was developed in COMSOL Multiphysics® software (Figure 1).

The model uses three different physics from the Subsurface Flow Module (Darcy’s Law, Heat Transfer in Porous Media, and Solute Transport), and the ODE and DAE nodes to link species transport and temperature dependent reactions. A mixed kinetic-equilibrium formulation is used to simulate geochemical reactions involving nine aqueous species. Precipitation and dissolution are modeled as slow reactions while local equilibrium reactions are expressed as fast reactions. To reduce the number of transport equations from nine to three, the activities of the species are grouped in three equations according to the Tableaux Method. The reaction rate of calcite is expressed by the PWP model based on three elementary reactions which are integrated in a reaction term in the Solute Transport interface. The rate constants and the equilibrium constants take into account the groundwater temperature, thus allowing coupling the temperature and the chemical reactions.

The results demonstrate that calcite dissolution and precipitation occur in the well and the surrounding environment during a typical 1-year operation involving heating and cooling (Figure 2 and 3). Thus, the presented numerical tool evidences the need for water treatment systems to provide SCW operation scheme.